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http://dx.doi.org/10.5659/JAIK.2022.38.11.141

Development of a Web-based Information System in Designing Biomimicry Architecture  

Kang, Junekyung (Dept. of Architecture, Kumoh National Institute of Technology)
Lee, Taegyu (Dept. of Architecture and Architectural Engineering, Seoul National University)
Yoo, Saewon (Dept. of Architecture and Architectural Engineering, Seoul National University)
Publication Information
Journal of the Architectural Institute of Korea / v.38, no.11, 2022 , pp. 141-152 More about this Journal
Abstract
Although biomimicry is being applied to sustainable architecture with all its possibilities, biomimicry architectural practices have mostly focused on the esthetic design method. The reason why biomimicry architecture is not activated in terms of environmental function could be due to the lack of information and the absence of a systematic methodology. Therefore, this study aims to provide a basis for constructing a web-based information system that could overcome these limitations and provide practical information. For this purpose, a theoretical review on the concept of biomimicry and its application along with biomimicry architecture cases were analyzed. In addition, website related theories were investigated to find actual construction plans. Based on these, the structure of a web-based information system and the type of information provided were presented.
Keywords
Biomimicry Architecture; Information System; Form Planning; Facade Planning; Case Study;
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  • Reference
1 Sadava, D., Hillis, D., Heller, H., Hacker, S. Willmer, P., Stone, G., & Ian, J. (2004). Life: The Science of Biology, 11th ed., W. H. Freeman.
2 Blanco, E., Zari, M., Raskin, K., & Clergeau, P. (2021). Urban ecosystem-level biomimicry and regenerative design: linking ecosystem functioning and urban built environments. Sustainability, 13(1), 1-12.
3 Sartori, J., Pal, U., & Chakrabarti, A. (2010). A methodolgy for supporting "transfer" in biomimetic design. Artificial Intelligence for Engineering Design, Analysis and Manufacturing, 24.
4 Gramann, J. (2004). Problemmodelle und Bionik als Methode. Ph.D. Dissertation, Technical University Munich.
5 Asefi, M. & Afzali, Z. (2016). Environmentally sustainable architecture: material-based technological design approach. Current World Environment, 11(1). 29.
6 El-Zeiny, R.M.A. (2012). Biomimicry as a problem solving methodology in interior architecture. Procedia-Social and Behavioral Sciences, 50, 502-512.   DOI
7 Vattam, S., Helms, M., & Goel, A. (2008). Compound analogical design: interaction between problem decomposition and analogical transfer in biologically inspired design. Proceedings of the 3rd International Conference of Design Computing and Cognition, 377-396.
8 Vattam, S., Helms, M., & Goel, A. (2010). A content account of creative analogies in biologically inspired design. Artificial Intelligence for Engineering Design, Analysis and Manufacturing, 24(4), 471.
9 Dorstelmann, M., Parascho, S., Prado, M., Menges, A., & Knippers, J. (2014). Integrative computational design methodologies for modular architectural fiber composite morphologies. Proceedings of the 34th Annual Conference of the Association for Computer Aided Design in Architecture(ACADIA), Los Angeles, 219-228.
10 Gruber, P. (2010). Biomimetics in Architecture. Springer Vienna Architecture.
11 Hill, B. (1997). Innovationsquelle Natur: Naturorientierte Innovationsstrategie fur Entwickler, Konstrukteure und Designer. Shaker Verlag.
12 Hill, B. (2005). Goal setting through contradiction analysis in the bionics-oriented construction process. Creativity and Innovation Management, 14(1), 59-65.   DOI
13 Kang, J., & Lee, J. (2014). A study on a research process for developing biomimicry architecture techniques. Proceedings of the Spring Annual Conference of AIK, 34(2), 37-38.
14 Mazzoleni, L. (2013). Architecture Follows Nature: Biomimetic Principles for Innovative Design. CRC Press.
15 Menges, A. (Ed.). (2015). Material Synthesis: Fusing the Physical and the Computaitonal. Wiley.
16 Rossin, K. (2010). Biomimicry: nature's design process versus the designer's process. WIT Transactions on Ecology and the Environment (Design and Nature V), 138, 559-570.   DOI
17 Helms, M.E., Vattam, S.S., & Goel, A.K. (2009). Biologically inspired design: process and products. Design Studies, 30(5), 606-622.   DOI
18 Kang, I. (1994). A Study on the Post-occupancy Evaluation Method for Apartment Houses Considering Design Information Characteristics (디자인 정보특성을고려한 공동주택 거주 후 평가방법에 관한 연구). Ph.D. Dissertation, Yonsei Univiersity.
19 Nagel, J., & Nagel, R. (2011). Abstracting biology for engineering design. International Journal Design Engineering, 4(1), 36.
20 Paton, C., & Davies, P. (2006). The seawater greenhouse cooling, fresh water and fresh produce from seawater. Proceedings of the 2nd International Conference on Water Resources & Arid Environment, Riyadh.
21 Speck, T., Speck, O., Beheshti, N., & McIntosh, A.C. (2008). Process sequences in biomimetic research. Design and Nature IV, 114, 3-11.
22 Kang, Y., & Kim, M. (2013). A study on biomimicry character and application appeared in the domestic green building. Journal of Basic Design & Art, 14(5), 3-13.
23 Menges, A., & Reichert, S. (2012). Material capacity: embedded responsiveness. Architectural Design, 82(2). 52-59.   DOI
24 Pawlyn, M. (2016). Biomimicry in Architecture. 2nd ed., RIBA Publishing.
25 Yeang, K., & Pawlyn, M. (2009). Seawater greenhouses and the sahara forest project. Architectural Design, 79(4), 122-123.   DOI
26 Zari, M.P. (2007). Biomimetic approaches to architectural design for increased sustainability. Proceedings of the Sustainable Building Conference, Auckland, 33.
27 Kang, J. (2017). Biomimicry Architectural Design Process: Integrated Approaches with Environmental Considerations. Ph.D. Dissertation, Seoul National University.
28 Datta, A. (2012). India's ecocity? environment, urbanisation, and mobility in the making of Lavasa. Environment and Planning C Government and Policy, 30, 982-996.   DOI
29 Pahl, G., & Beitz, W. (1996). Engineering Design: A Systematic Approach, Springer.
30 Benyus, J. (2002). Biomimicry: Innovation Inspired by Nature. Harper Perennial.
31 Baumeister, D. (2014). Biomimicry Resource Handbook: A Seed Bank of Best Practices. Biomimicry 3.8.
32 Schild, K., Herstatt, C., & Luthje, C. (2004). How to Use Analogies for Breakthrough Innovations. Working Paper, No. 24, Hamburg University of Technology(TUHH), Institute for Technology and Innovation Management(TIM).